/*
* Copyright (C) 2000 Red Hat, Inc
* mediaLib integration Copyright (c) 2001-2007 Sun Microsystems, Inc.
* All rights reserved. (Brian Cameron, Dmitriy Demin, James Cheng,
* Padraig O'Briain)
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, see .
*/
#include "config.h"
#include
#include
#include "../fallback-c89.c"
#include "pixops.h"
#include "pixops-internal.h"
#define SUBSAMPLE_BITS 4
#define SUBSAMPLE (1 << SUBSAMPLE_BITS)
#define SUBSAMPLE_MASK ((1 << SUBSAMPLE_BITS)-1)
#define SCALE_SHIFT 16
static void
_pixops_scale_real (guchar *dest_buf,
int render_x0,
int render_y0,
int render_x1,
int render_y1,
int dest_rowstride,
int dest_channels,
gboolean dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
gboolean src_has_alpha,
double scale_x,
double scale_y,
PixopsInterpType interp_type);
typedef struct _PixopsFilter PixopsFilter;
typedef struct _PixopsFilterDimension PixopsFilterDimension;
struct _PixopsFilterDimension
{
int n;
double offset;
double *weights;
};
struct _PixopsFilter
{
PixopsFilterDimension x;
PixopsFilterDimension y;
double overall_alpha;
};
typedef guchar *(*PixopsLineFunc) (int *weights, int n_x, int n_y,
guchar *dest, int dest_x, guchar *dest_end,
int dest_channels, int dest_has_alpha,
guchar **src, int src_channels,
gboolean src_has_alpha, int x_init,
int x_step, int src_width, int check_size,
guint32 color1, guint32 color2);
typedef void (*PixopsPixelFunc) (guchar *dest, int dest_x, int dest_channels,
int dest_has_alpha, int src_has_alpha,
int check_size, guint32 color1,
guint32 color2,
guint r, guint g, guint b, guint a);
#ifdef USE_MEDIALIB
#include
#include
#include
#ifdef HAVE_STRINGS_H
#include
#endif
#ifdef HAVE_STRING_H
#include
#endif
#if defined(HAVE_SYS_SYSTEMINFO_H)
#include
#elif defined(HAVE_SYS_SYSINFO_H)
#include
#endif
static void pixops_medialib_composite (guchar *dest_buf,
int dest_width,
int dest_height,
int dest_rowstride,
int dest_channels,
int dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
int src_has_alpha,
int dest_x,
int dest_y,
int dest_region_width,
int dest_region_height,
double offset_x,
double offset_y,
double scale_x,
double scale_y,
PixopsInterpType interp_type,
int overall_alpha);
static void pixops_medialib_scale (guchar *dest_buf,
int dest_width,
int dest_height,
int dest_rowstride,
int dest_channels,
int dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
int src_has_alpha,
int dest_x,
int dest_y,
int dest_region_width,
int dest_region_height,
double offset_x,
double offset_y,
double scale_x,
double scale_y,
PixopsInterpType interp_type);
typedef struct _mlInterp mlInterp;
struct _mlInterp
{
double tx;
double ty;
PixopsFilter po_filter;
void *interp_table;
};
static gboolean medialib_initialized = FALSE;
static gboolean use_medialib = TRUE;
/*
* Sun mediaLib(tm) support.
*
* http://www.sun.com/processors/vis/mlib.html
*
*/
static void
_pixops_use_medialib ()
{
char *mlib_version_string;
char sys_info[257];
long count;
medialib_initialized = TRUE;
if (getenv ("GDK_DISABLE_MEDIALIB"))
{
use_medialib = FALSE;
return;
}
/*
* The imaging functions we want to use were added in mediaLib version 2.
* So turn off mediaLib support if the user has an older version.
* mlib_version returns a string in this format:
*
* mediaLib:0210:20011101:v8plusa
* ^^^^^^^^ ^^^^ ^^^^^^^^ ^^^^^^^
* libname vers build ISALIST identifier
* date (in this case sparcv8plus+vis)
*
* The first 2 digits of the version are the major version. The 3rd digit
* is the minor version, and the 4th digit is the micro version. So the
* above string corresponds to version 2.1.0. In the following test we only
* care about the major version.
*/
mlib_version_string = mlib_version ();
count = sysinfo (SI_ARCHITECTURE, &sys_info[0], 257);
if (count != -1)
{
if (strcmp (sys_info, "i386") == 0)
{
char *mlib_target_isa = &mlib_version_string[23];
/*
* For x86 processors mediaLib generic C implementation
* does not give any performance advantage so disable it
*/
if (strncmp (mlib_target_isa, "sse", 3) != 0)
{
use_medialib = FALSE;
return;
}
/*
* For x86 processors use of libumem conflicts with
* mediaLib, so avoid using it.
*/
if (dlsym (RTLD_PROBE, "umem_alloc") != NULL)
{
use_medialib = FALSE;
return;
}
}
}
else
{
/* Failed to get system architecture, disable mediaLib anyway */
use_medialib = FALSE;
return;
}
}
#endif
static int
get_check_shift (int check_size)
{
int check_shift = 0;
g_return_val_if_fail (check_size >= 0, 4);
while (!(check_size & 1))
{
check_shift++;
check_size >>= 1;
}
return check_shift;
}
static void
pixops_scale_nearest (guchar *dest_buf,
int render_x0,
int render_y0,
int render_x1,
int render_y1,
int dest_rowstride,
int dest_channels,
gboolean dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
gboolean src_has_alpha,
double scale_x,
double scale_y)
{
gint64 i;
gint64 x;
gint64 x_step = (1 << SCALE_SHIFT) / scale_x;
gint64 y_step = (1 << SCALE_SHIFT) / scale_y;
gint64 xmax, xstart, xstop, x_pos, y_pos;
const guchar *p;
#define INNER_LOOP(SRC_CHANNELS,DEST_CHANNELS,ASSIGN_PIXEL) \
xmax = x + (render_x1 - render_x0) * x_step; \
xstart = MIN (0, xmax); \
xstop = MIN (src_width << SCALE_SHIFT, xmax); \
p = src + (CLAMP (x, xstart, xstop) >> SCALE_SHIFT) * SRC_CHANNELS; \
while (x < xstart) \
{ \
ASSIGN_PIXEL; \
dest += DEST_CHANNELS; \
x += x_step; \
} \
while (x < xstop) \
{ \
p = src + (x >> SCALE_SHIFT) * SRC_CHANNELS; \
ASSIGN_PIXEL; \
dest += DEST_CHANNELS; \
x += x_step; \
} \
x_pos = x >> SCALE_SHIFT; \
p = src + CLAMP (x_pos, 0, src_width - 1) * SRC_CHANNELS; \
while (x < xmax) \
{ \
ASSIGN_PIXEL; \
dest += DEST_CHANNELS; \
x += x_step; \
}
for (i = 0; i < (render_y1 - render_y0); i++)
{
const guchar *src;
guchar *dest;
y_pos = ((i + render_y0) * y_step + y_step / 2) >> SCALE_SHIFT;
y_pos = CLAMP (y_pos, 0, src_height - 1);
src = src_buf + (gsize)y_pos * src_rowstride;
dest = dest_buf + (gsize)i * dest_rowstride;
x = render_x0 * x_step + x_step / 2;
if (src_channels == 3)
{
if (dest_channels == 3)
{
INNER_LOOP (3, 3, dest[0]=p[0];dest[1]=p[1];dest[2]=p[2]);
}
else
{
INNER_LOOP (3, 4, dest[0]=p[0];dest[1]=p[1];dest[2]=p[2];dest[3]=0xff);
}
}
else if (src_channels == 4)
{
if (dest_channels == 3)
{
INNER_LOOP (4, 3, dest[0]=p[0];dest[1]=p[1];dest[2]=p[2]);
}
else
{
guint32 *p32;
INNER_LOOP(4, 4, p32=(guint32*)dest;*p32=*((guint32*)p));
}
}
}
}
static void
pixops_composite_nearest (guchar *dest_buf,
int render_x0,
int render_y0,
int render_x1,
int render_y1,
int dest_rowstride,
int dest_channels,
gboolean dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
gboolean src_has_alpha,
double scale_x,
double scale_y,
int overall_alpha)
{
gint64 i;
gint64 x;
gint64 x_step = (1 << SCALE_SHIFT) / scale_x;
gint64 y_step = (1 << SCALE_SHIFT) / scale_y;
gint64 xmax, xstart, xstop, x_pos, y_pos;
const guchar *p;
unsigned int a0;
for (i = 0; i < (render_y1 - render_y0); i++)
{
const guchar *src;
guchar *dest;
y_pos = ((i + render_y0) * y_step + y_step / 2) >> SCALE_SHIFT;
y_pos = CLAMP (y_pos, 0, src_height - 1);
src = src_buf + (gsize)y_pos * src_rowstride;
dest = dest_buf + (gsize)i * dest_rowstride;
x = render_x0 * x_step + x_step / 2;
INNER_LOOP(src_channels, dest_channels,
if (src_has_alpha)
a0 = (p[3] * overall_alpha) / 0xff;
else
a0 = overall_alpha;
switch (a0)
{
case 0:
break;
case 255:
dest[0] = p[0];
dest[1] = p[1];
dest[2] = p[2];
if (dest_has_alpha)
dest[3] = 0xff;
break;
default:
if (dest_has_alpha)
{
unsigned int w0 = 0xff * a0;
unsigned int w1 = (0xff - a0) * dest[3];
unsigned int w = w0 + w1;
dest[0] = (w0 * p[0] + w1 * dest[0]) / w;
dest[1] = (w0 * p[1] + w1 * dest[1]) / w;
dest[2] = (w0 * p[2] + w1 * dest[2]) / w;
dest[3] = w / 0xff;
}
else
{
unsigned int a1 = 0xff - a0;
unsigned int tmp;
tmp = a0 * p[0] + a1 * dest[0] + 0x80;
dest[0] = (tmp + (tmp >> 8)) >> 8;
tmp = a0 * p[1] + a1 * dest[1] + 0x80;
dest[1] = (tmp + (tmp >> 8)) >> 8;
tmp = a0 * p[2] + a1 * dest[2] + 0x80;
dest[2] = (tmp + (tmp >> 8)) >> 8;
}
break;
}
);
}
}
static void
pixops_composite_nearest_noscale (guchar *dest_buf,
int render_x0,
int render_y0,
int render_x1,
int render_y1,
int dest_rowstride,
int dest_channels,
gboolean dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
gboolean src_has_alpha,
int overall_alpha)
{
gint64 i;
gint64 x;
gint64 xmax, xstart, xstop, y_pos;
const guchar *p;
unsigned int a0;
#define INNER_LOOP_NOSCALE(SRC_CHANNELS,DEST_CHANNELS,ASSIGN_PIXEL) \
xmax = x + (render_x1 - render_x0); \
xstart = MIN (0, xmax); \
xstop = MIN (src_width, xmax); \
p = src + CLAMP (x, xstart, xstop) * SRC_CHANNELS; \
while (x < xstart) \
{ \
ASSIGN_PIXEL; \
dest += DEST_CHANNELS; \
x++; \
} \
p = src + x * SRC_CHANNELS; \
while (x < xstop) \
{ \
ASSIGN_PIXEL; \
dest += DEST_CHANNELS; \
x++; \
p += SRC_CHANNELS; \
} \
p = src + CLAMP (x, 0, src_width - 1) * SRC_CHANNELS; \
while (x < xmax) \
{ \
ASSIGN_PIXEL; \
dest += DEST_CHANNELS; \
x++; \
}
for (i = 0; i < (render_y1 - render_y0); i++)
{
const guchar *src;
guchar *dest;
y_pos = i + render_y0;
y_pos = CLAMP (y_pos, 0, src_height - 1);
src = src_buf + (gsize)y_pos * src_rowstride;
dest = dest_buf + (gsize)i * dest_rowstride;
x = render_x0;
INNER_LOOP_NOSCALE(src_channels, dest_channels,
if (src_has_alpha)
a0 = (p[3] * overall_alpha) / 0xff;
else
a0 = overall_alpha;
switch (a0)
{
case 0:
break;
case 255:
dest[0] = p[0];
dest[1] = p[1];
dest[2] = p[2];
if (dest_has_alpha)
dest[3] = 0xff;
break;
default:
if (dest_has_alpha)
{
unsigned int w0 = 0xff * a0;
unsigned int w1 = (0xff - a0) * dest[3];
unsigned int w = w0 + w1;
dest[0] = (w0 * p[0] + w1 * dest[0]) / w;
dest[1] = (w0 * p[1] + w1 * dest[1]) / w;
dest[2] = (w0 * p[2] + w1 * dest[2]) / w;
dest[3] = w / 0xff;
}
else
{
unsigned int a1 = 0xff - a0;
unsigned int tmp;
tmp = a0 * p[0] + a1 * dest[0] + 0x80;
dest[0] = (tmp + (tmp >> 8)) >> 8;
tmp = a0 * p[1] + a1 * dest[1] + 0x80;
dest[1] = (tmp + (tmp >> 8)) >> 8;
tmp = a0 * p[2] + a1 * dest[2] + 0x80;
dest[2] = (tmp + (tmp >> 8)) >> 8;
}
break;
}
);
}
}
#undef INNER_LOOP_NOSCALE
static void
pixops_composite_color_nearest (guchar *dest_buf,
int render_x0,
int render_y0,
int render_x1,
int render_y1,
int dest_rowstride,
int dest_channels,
gboolean dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
gboolean src_has_alpha,
double scale_x,
double scale_y,
int overall_alpha,
int check_x,
int check_y,
int check_size,
guint32 color1,
guint32 color2)
{
gint64 i, j;
gint64 x;
gint64 x_step = (1 << SCALE_SHIFT) / scale_x;
gint64 y_step = (1 << SCALE_SHIFT) / scale_y;
int r1, g1, b1, r2, g2, b2;
int check_shift = get_check_shift (check_size);
gint64 xmax, xstart, xstop, x_pos, y_pos;
const guchar *p;
unsigned int a0;
for (i = 0; i < (render_y1 - render_y0); i++)
{
const guchar *src;
guchar *dest;
y_pos = ((i + render_y0) * y_step + y_step / 2) >> SCALE_SHIFT;
y_pos = CLAMP (y_pos, 0, src_height - 1);
src = src_buf + (gsize)y_pos * src_rowstride;
dest = dest_buf + (gsize)i * dest_rowstride;
x = render_x0 * x_step + x_step / 2;
if (((i + check_y) >> check_shift) & 1)
{
r1 = (color2 & 0xff0000) >> 16;
g1 = (color2 & 0xff00) >> 8;
b1 = color2 & 0xff;
r2 = (color1 & 0xff0000) >> 16;
g2 = (color1 & 0xff00) >> 8;
b2 = color1 & 0xff;
}
else
{
r1 = (color1 & 0xff0000) >> 16;
g1 = (color1 & 0xff00) >> 8;
b1 = color1 & 0xff;
r2 = (color2 & 0xff0000) >> 16;
g2 = (color2 & 0xff00) >> 8;
b2 = color2 & 0xff;
}
j = 0;
INNER_LOOP(src_channels, dest_channels,
if (src_has_alpha)
a0 = (p[3] * overall_alpha + 0xff) >> 8;
else
a0 = overall_alpha;
switch (a0)
{
case 0:
if (((j + check_x) >> check_shift) & 1)
{
dest[0] = r2;
dest[1] = g2;
dest[2] = b2;
}
else
{
dest[0] = r1;
dest[1] = g1;
dest[2] = b1;
}
break;
case 255:
dest[0] = p[0];
dest[1] = p[1];
dest[2] = p[2];
break;
default:
{
unsigned int tmp;
if (((j + check_x) >> check_shift) & 1)
{
tmp = ((int) p[0] - r2) * a0;
dest[0] = r2 + ((tmp + (tmp >> 8) + 0x80) >> 8);
tmp = ((int) p[1] - g2) * a0;
dest[1] = g2 + ((tmp + (tmp >> 8) + 0x80) >> 8);
tmp = ((int) p[2] - b2) * a0;
dest[2] = b2 + ((tmp + (tmp >> 8) + 0x80) >> 8);
}
else
{
tmp = ((int) p[0] - r1) * a0;
dest[0] = r1 + ((tmp + (tmp >> 8) + 0x80) >> 8);
tmp = ((int) p[1] - g1) * a0;
dest[1] = g1 + ((tmp + (tmp >> 8) + 0x80) >> 8);
tmp = ((int) p[2] - b1) * a0;
dest[2] = b1 + ((tmp + (tmp >> 8) + 0x80) >> 8);
}
}
break;
}
if (dest_channels == 4)
dest[3] = 0xff;
j++;
);
}
}
#undef INNER_LOOP
static void
composite_pixel (guchar *dest, int dest_x, int dest_channels, int dest_has_alpha,
int src_has_alpha, int check_size, guint32 color1, guint32 color2,
guint r, guint g, guint b, guint a)
{
if (dest_has_alpha)
{
unsigned int w0 = a - (a >> 8);
unsigned int w1 = ((0xff0000 - a) >> 8) * dest[3];
unsigned int w = w0 + w1;
if (w != 0)
{
dest[0] = (r - (r >> 8) + w1 * dest[0]) / w;
dest[1] = (g - (g >> 8) + w1 * dest[1]) / w;
dest[2] = (b - (b >> 8) + w1 * dest[2]) / w;
dest[3] = w / 0xff00;
}
else
{
dest[0] = 0;
dest[1] = 0;
dest[2] = 0;
dest[3] = 0;
}
}
else
{
dest[0] = (r + (0xff0000 - a) * dest[0]) / 0xff0000;
dest[1] = (g + (0xff0000 - a) * dest[1]) / 0xff0000;
dest[2] = (b + (0xff0000 - a) * dest[2]) / 0xff0000;
}
}
static guchar *
composite_line (int *weights, int n_x, int n_y,
guchar *dest, int dest_x, guchar *dest_end, int dest_channels, int dest_has_alpha,
guchar **src, int src_channels, gboolean src_has_alpha,
int x_init, int x_step, int src_width,
int check_size, guint32 color1, guint32 color2)
{
int x = x_init;
int i, j;
while (dest < dest_end)
{
int x_scaled = x >> SCALE_SHIFT;
unsigned int r = 0, g = 0, b = 0, a = 0;
int *pixel_weights;
pixel_weights = weights + ((x >> (SCALE_SHIFT - SUBSAMPLE_BITS)) & SUBSAMPLE_MASK) * n_x * n_y;
for (i=0; i> 8);
unsigned int w1 = ((0xff0000 - a) >> 8) * dest[3];
unsigned int w = w0 + w1;
if (w != 0)
{
dest[0] = (r - (r >> 8) + w1 * dest[0]) / w;
dest[1] = (g - (g >> 8) + w1 * dest[1]) / w;
dest[2] = (b - (b >> 8) + w1 * dest[2]) / w;
dest[3] = w / 0xff00;
}
else
{
dest[0] = 0;
dest[1] = 0;
dest[2] = 0;
dest[3] = 0;
}
}
else
{
dest[0] = (r + (0xff0000 - a) * dest[0]) / 0xff0000;
dest[1] = (g + (0xff0000 - a) * dest[1]) / 0xff0000;
dest[2] = (b + (0xff0000 - a) * dest[2]) / 0xff0000;
}
dest += dest_channels;
x += x_step;
}
return dest;
}
static guchar *
composite_line_22_4a4 (int *weights, int n_x, int n_y,
guchar *dest, int dest_x, guchar *dest_end, int dest_channels, int dest_has_alpha,
guchar **src, int src_channels, gboolean src_has_alpha,
int x_init, int x_step, int src_width,
int check_size, guint32 color1, guint32 color2)
{
int x = x_init;
guchar *src0 = src[0];
guchar *src1 = src[1];
g_return_val_if_fail (src_channels != 3, dest);
g_return_val_if_fail (src_has_alpha, dest);
while (dest < dest_end)
{
int x_scaled = x >> SCALE_SHIFT;
unsigned int r, g, b, a, ta;
int *pixel_weights;
guchar *q0, *q1;
int w1, w2, w3, w4;
q0 = src0 + x_scaled * 4;
q1 = src1 + x_scaled * 4;
pixel_weights = (int *)((char *)weights +
((x >> (SCALE_SHIFT - SUBSAMPLE_BITS - 4)) & (SUBSAMPLE_MASK << 4)));
w1 = pixel_weights[0];
w2 = pixel_weights[1];
w3 = pixel_weights[2];
w4 = pixel_weights[3];
a = w1 * q0[3];
r = a * q0[0];
g = a * q0[1];
b = a * q0[2];
ta = w2 * q0[7];
r += ta * q0[4];
g += ta * q0[5];
b += ta * q0[6];
a += ta;
ta = w3 * q1[3];
r += ta * q1[0];
g += ta * q1[1];
b += ta * q1[2];
a += ta;
ta = w4 * q1[7];
r += ta * q1[4];
g += ta * q1[5];
b += ta * q1[6];
a += ta;
dest[0] = ((0xff0000 - a) * dest[0] + r) >> 24;
dest[1] = ((0xff0000 - a) * dest[1] + g) >> 24;
dest[2] = ((0xff0000 - a) * dest[2] + b) >> 24;
dest[3] = a >> 16;
dest += 4;
x += x_step;
}
return dest;
}
#ifdef USE_MMX
static guchar *
composite_line_22_4a4_mmx_stub (int *weights, int n_x, int n_y, guchar *dest,
int dest_x, guchar *dest_end,
int dest_channels, int dest_has_alpha,
guchar **src, int src_channels,
gboolean src_has_alpha, int x_init,
int x_step, int src_width, int check_size,
guint32 color1, guint32 color2)
{
guint32 mmx_weights[16][8];
int j;
for (j=0; j<16; j++)
{
mmx_weights[j][0] = 0x00010001 * (weights[4*j] >> 8);
mmx_weights[j][1] = 0x00010001 * (weights[4*j] >> 8);
mmx_weights[j][2] = 0x00010001 * (weights[4*j + 1] >> 8);
mmx_weights[j][3] = 0x00010001 * (weights[4*j + 1] >> 8);
mmx_weights[j][4] = 0x00010001 * (weights[4*j + 2] >> 8);
mmx_weights[j][5] = 0x00010001 * (weights[4*j + 2] >> 8);
mmx_weights[j][6] = 0x00010001 * (weights[4*j + 3] >> 8);
mmx_weights[j][7] = 0x00010001 * (weights[4*j + 3] >> 8);
}
return _pixops_composite_line_22_4a4_mmx (mmx_weights, dest, src[0], src[1],
x_step, dest_end, x_init);
}
#endif /* USE_MMX */
static void
composite_pixel_color (guchar *dest, int dest_x, int dest_channels,
int dest_has_alpha, int src_has_alpha, int check_size,
guint32 color1, guint32 color2, guint r, guint g,
guint b, guint a)
{
int dest_r, dest_g, dest_b;
int check_shift = get_check_shift (check_size);
if ((dest_x >> check_shift) & 1)
{
dest_r = (color2 & 0xff0000) >> 16;
dest_g = (color2 & 0xff00) >> 8;
dest_b = color2 & 0xff;
}
else
{
dest_r = (color1 & 0xff0000) >> 16;
dest_g = (color1 & 0xff00) >> 8;
dest_b = color1 & 0xff;
}
dest[0] = ((0xff0000 - a) * dest_r + r) >> 24;
dest[1] = ((0xff0000 - a) * dest_g + g) >> 24;
dest[2] = ((0xff0000 - a) * dest_b + b) >> 24;
if (dest_has_alpha)
dest[3] = 0xff;
else if (dest_channels == 4)
dest[3] = a >> 16;
}
static guchar *
composite_line_color (int *weights, int n_x, int n_y, guchar *dest,
int dest_x, guchar *dest_end, int dest_channels,
int dest_has_alpha, guchar **src, int src_channels,
gboolean src_has_alpha, int x_init, int x_step,
int src_width, int check_size, guint32 color1,
guint32 color2)
{
int x = x_init;
int i, j;
int check_shift = get_check_shift (check_size);
int dest_r1, dest_g1, dest_b1;
int dest_r2, dest_g2, dest_b2;
g_return_val_if_fail (check_size != 0, dest);
dest_r1 = (color1 & 0xff0000) >> 16;
dest_g1 = (color1 & 0xff00) >> 8;
dest_b1 = color1 & 0xff;
dest_r2 = (color2 & 0xff0000) >> 16;
dest_g2 = (color2 & 0xff00) >> 8;
dest_b2 = color2 & 0xff;
while (dest < dest_end)
{
int x_scaled = x >> SCALE_SHIFT;
unsigned int r = 0, g = 0, b = 0, a = 0;
int *pixel_weights;
pixel_weights = weights + ((x >> (SCALE_SHIFT - SUBSAMPLE_BITS)) & SUBSAMPLE_MASK) * n_x * n_y;
for (i=0; i> check_shift) & 1)
{
dest[0] = ((0xff0000 - a) * dest_r2 + r) >> 24;
dest[1] = ((0xff0000 - a) * dest_g2 + g) >> 24;
dest[2] = ((0xff0000 - a) * dest_b2 + b) >> 24;
}
else
{
dest[0] = ((0xff0000 - a) * dest_r1 + r) >> 24;
dest[1] = ((0xff0000 - a) * dest_g1 + g) >> 24;
dest[2] = ((0xff0000 - a) * dest_b1 + b) >> 24;
}
if (dest_has_alpha)
dest[3] = 0xff;
else if (dest_channels == 4)
dest[3] = a >> 16;
dest += dest_channels;
x += x_step;
dest_x++;
}
return dest;
}
#ifdef USE_MMX
static guchar *
composite_line_color_22_4a4_mmx_stub (int *weights, int n_x, int n_y,
guchar *dest, int dest_x,
guchar *dest_end, int dest_channels,
int dest_has_alpha, guchar **src,
int src_channels, gboolean src_has_alpha,
int x_init, int x_step, int src_width,
int check_size, guint32 color1,
guint32 color2)
{
guint32 mmx_weights[16][8];
int check_shift = get_check_shift (check_size);
int colors[4];
int j;
for (j=0; j<16; j++)
{
mmx_weights[j][0] = 0x00010001 * (weights[4*j] >> 8);
mmx_weights[j][1] = 0x00010001 * (weights[4*j] >> 8);
mmx_weights[j][2] = 0x00010001 * (weights[4*j + 1] >> 8);
mmx_weights[j][3] = 0x00010001 * (weights[4*j + 1] >> 8);
mmx_weights[j][4] = 0x00010001 * (weights[4*j + 2] >> 8);
mmx_weights[j][5] = 0x00010001 * (weights[4*j + 2] >> 8);
mmx_weights[j][6] = 0x00010001 * (weights[4*j + 3] >> 8);
mmx_weights[j][7] = 0x00010001 * (weights[4*j + 3] >> 8);
}
colors[0] = (color1 & 0xff00) << 8 | (color1 & 0xff);
colors[1] = (color1 & 0xff0000) >> 16;
colors[2] = (color2 & 0xff00) << 8 | (color2 & 0xff);
colors[3] = (color2 & 0xff0000) >> 16;
return _pixops_composite_line_color_22_4a4_mmx (mmx_weights, dest, src[0],
src[1], x_step, dest_end, x_init, dest_x, check_shift, colors);
}
#endif /* USE_MMX */
static void
scale_pixel (guchar *dest, int dest_x, int dest_channels, int dest_has_alpha,
int src_has_alpha, int check_size, guint32 color1, guint32 color2,
guint r, guint g, guint b, guint a)
{
if (src_has_alpha)
{
if (a)
{
dest[0] = r / a;
dest[1] = g / a;
dest[2] = b / a;
dest[3] = a >> 16;
}
else
{
dest[0] = 0;
dest[1] = 0;
dest[2] = 0;
dest[3] = 0;
}
}
else
{
dest[0] = (r + 0xffffff) >> 24;
dest[1] = (g + 0xffffff) >> 24;
dest[2] = (b + 0xffffff) >> 24;
if (dest_has_alpha)
dest[3] = 0xff;
}
}
static guchar *
scale_line (int *weights, int n_x, int n_y, guchar *dest, int dest_x,
guchar *dest_end, int dest_channels, int dest_has_alpha,
guchar **src, int src_channels, gboolean src_has_alpha, int x_init,
int x_step, int src_width, int check_size, guint32 color1,
guint32 color2)
{
int x = x_init;
int i, j;
while (dest < dest_end)
{
int x_scaled = x >> SCALE_SHIFT;
int *pixel_weights;
pixel_weights = weights +
((x >> (SCALE_SHIFT - SUBSAMPLE_BITS)) & SUBSAMPLE_MASK) * n_x * n_y;
if (src_has_alpha)
{
unsigned int r = 0, g = 0, b = 0, a = 0;
for (i=0; i> 16;
}
else
{
dest[0] = 0;
dest[1] = 0;
dest[2] = 0;
dest[3] = 0;
}
}
else
{
unsigned int r = 0, g = 0, b = 0;
for (i=0; i> 16;
dest[1] = (g + 0xffff) >> 16;
dest[2] = (b + 0xffff) >> 16;
if (dest_has_alpha)
dest[3] = 0xff;
}
dest += dest_channels;
x += x_step;
}
return dest;
}
#ifdef USE_MMX
static guchar *
scale_line_22_33_mmx_stub (int *weights, int n_x, int n_y, guchar *dest,
int dest_x, guchar *dest_end, int dest_channels,
int dest_has_alpha, guchar **src, int src_channels,
gboolean src_has_alpha, int x_init, int x_step,
int src_width, int check_size, guint32 color1,
guint32 color2)
{
guint32 mmx_weights[16][8];
int j;
for (j=0; j<16; j++)
{
mmx_weights[j][0] = 0x00010001 * (weights[4*j] >> 8);
mmx_weights[j][1] = 0x00010001 * (weights[4*j] >> 8);
mmx_weights[j][2] = 0x00010001 * (weights[4*j + 1] >> 8);
mmx_weights[j][3] = 0x00010001 * (weights[4*j + 1] >> 8);
mmx_weights[j][4] = 0x00010001 * (weights[4*j + 2] >> 8);
mmx_weights[j][5] = 0x00010001 * (weights[4*j + 2] >> 8);
mmx_weights[j][6] = 0x00010001 * (weights[4*j + 3] >> 8);
mmx_weights[j][7] = 0x00010001 * (weights[4*j + 3] >> 8);
}
return _pixops_scale_line_22_33_mmx (mmx_weights, dest, src[0], src[1],
x_step, dest_end, x_init);
}
#endif /* USE_MMX */
static guchar *
scale_line_22_33 (int *weights, int n_x, int n_y, guchar *dest, int dest_x,
guchar *dest_end, int dest_channels, int dest_has_alpha,
guchar **src, int src_channels, gboolean src_has_alpha,
int x_init, int x_step, int src_width,
int check_size, guint32 color1, guint32 color2)
{
int x = x_init;
guchar *src0 = src[0];
guchar *src1 = src[1];
while (dest < dest_end)
{
unsigned int r, g, b;
int x_scaled = x >> SCALE_SHIFT;
int *pixel_weights;
guchar *q0, *q1;
int w1, w2, w3, w4;
q0 = src0 + x_scaled * 3;
q1 = src1 + x_scaled * 3;
pixel_weights = weights +
((x >> (SCALE_SHIFT - SUBSAMPLE_BITS)) & SUBSAMPLE_MASK) * 4;
w1 = pixel_weights[0];
w2 = pixel_weights[1];
w3 = pixel_weights[2];
w4 = pixel_weights[3];
r = w1 * q0[0];
g = w1 * q0[1];
b = w1 * q0[2];
r += w2 * q0[3];
g += w2 * q0[4];
b += w2 * q0[5];
r += w3 * q1[0];
g += w3 * q1[1];
b += w3 * q1[2];
r += w4 * q1[3];
g += w4 * q1[4];
b += w4 * q1[5];
dest[0] = (r + 0x8000) >> 16;
dest[1] = (g + 0x8000) >> 16;
dest[2] = (b + 0x8000) >> 16;
dest += 3;
x += x_step;
}
return dest;
}
static void
process_pixel (int *weights, int n_x, int n_y, guchar *dest, int dest_x,
int dest_channels, int dest_has_alpha, guchar **src,
int src_channels, gboolean src_has_alpha, int x_start,
int src_width, int check_size, guint32 color1, guint32 color2,
PixopsPixelFunc pixel_func)
{
unsigned int r = 0, g = 0, b = 0, a = 0;
int i, j;
for (i=0; i= 0 && c != 0 && remaining != 0; i--)
if (*(weights + i) + c >= 0)
{
*(weights + i) += c;
remaining -= c;
if ((0 < remaining && remaining < c) ||
(0 > remaining && remaining > c))
c = remaining;
}
}
}
static int *
make_filter_table (PixopsFilter *filter)
{
int i_offset, j_offset;
int n_x = filter->x.n;
int n_y = filter->y.n;
int *weights;
/* check n_x doesn't overflow */
if (G_MAXINT / (SUBSAMPLE * SUBSAMPLE) < n_x)
return NULL;
/* check n_y doesn't overflow */
if (G_MAXINT / (SUBSAMPLE * SUBSAMPLE * n_x) < n_y)
return NULL;
weights = g_try_new (int, SUBSAMPLE * SUBSAMPLE * n_x * n_y);
if (!weights)
return NULL; /* overflow, bail */
for (i_offset=0; i_offset < SUBSAMPLE; i_offset++)
for (j_offset=0; j_offset < SUBSAMPLE; j_offset++)
{
double weight;
int *pixel_weights = weights + ((i_offset*SUBSAMPLE) + j_offset) * n_x * n_y;
int total = 0;
int i, j;
for (i=0; i < n_y; i++)
for (j=0; j < n_x; j++)
{
weight = filter->x.weights[(j_offset * n_x) + j] *
filter->y.weights[(i_offset * n_y) + i] *
filter->overall_alpha * 65536 + 0.5;
total += (int)weight;
*(pixel_weights + n_x * i + j) = weight;
}
correct_total (pixel_weights, n_x, n_y, total, filter->overall_alpha);
}
return weights;
}
static void
pixops_process (guchar *dest_buf,
int render_x0,
int render_y0,
int render_x1,
int render_y1,
int dest_rowstride,
int dest_channels,
gboolean dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
gboolean src_has_alpha,
double scale_x,
double scale_y,
int check_x,
int check_y,
int check_size,
guint32 color1,
guint32 color2,
PixopsFilter *filter,
PixopsLineFunc line_func,
PixopsPixelFunc pixel_func)
{
gint64 i, j;
gint64 x, y; /* X and Y position in source (fixed_point) */
guchar **line_bufs;
int *filter_weights;
gint64 x_step;
gint64 y_step;
int check_shift;
gint64 scaled_x_offset;
gint64 run_end_x;
gint64 run_end_index;
x_step = (1 << SCALE_SHIFT) / scale_x; /* X step in source (fixed point) */
y_step = (1 << SCALE_SHIFT) / scale_y; /* Y step in source (fixed point) */
if (x_step == 0 || y_step == 0)
return; /* overflow, bail out */
filter_weights = make_filter_table (filter);
if (!filter_weights)
return; /* overflow, bail out */
line_bufs = g_new (guchar *, filter->y.n);
check_shift = check_size ? get_check_shift (check_size) : 0;
scaled_x_offset = floor (filter->x.offset * (1 << SCALE_SHIFT));
/* Compute the index where we run off the end of the source buffer. The
* furthest source pixel we access at index i is:
*
* ((render_x0 + i) * x_step + scaled_x_offset) >> SCALE_SHIFT + filter->x.n - 1
*
* So, run_end_index is the smallest i for which this pixel is src_width,
* i.e, for which:
*
* (i + render_x0) * x_step >= ((src_width - filter->x.n + 1) << SCALE_SHIFT) - scaled_x_offset
*
*/
#define MYDIV(a,b) ((a) > 0 ? (a) / (b) : ((a) - (b) + 1) / (b)) /* Division so that -1/5 = -1 */
run_end_x = (((src_width - filter->x.n + 1) << SCALE_SHIFT) - scaled_x_offset);
run_end_index = MYDIV (run_end_x + x_step - 1, x_step) - render_x0;
run_end_index = MIN (run_end_index, render_x1 - render_x0);
y = render_y0 * y_step + floor (filter->y.offset * (1 << SCALE_SHIFT));
for (i = 0; i < (render_y1 - render_y0); i++)
{
int dest_x;
int y_start = y >> SCALE_SHIFT;
int x_start;
int *run_weights = filter_weights +
((y >> (SCALE_SHIFT - SUBSAMPLE_BITS)) & SUBSAMPLE_MASK) *
filter->x.n * filter->y.n * SUBSAMPLE;
guchar *new_outbuf;
guint32 tcolor1, tcolor2;
guchar *outbuf = dest_buf + (gsize)dest_rowstride * i;
guchar *outbuf_end = outbuf + dest_channels * (render_x1 - render_x0);
if (((i + check_y) >> check_shift) & 1)
{
tcolor1 = color2;
tcolor2 = color1;
}
else
{
tcolor1 = color1;
tcolor2 = color2;
}
for (j=0; jy.n; j++)
{
if (y_start < 0)
line_bufs[j] = (guchar *)src_buf;
else if (y_start < src_height)
line_bufs[j] = (guchar *)src_buf + (gsize)src_rowstride * y_start;
else
line_bufs[j] = (guchar *)src_buf + (gsize)src_rowstride * (src_height - 1);
y_start++;
}
dest_x = check_x;
x = render_x0 * x_step + scaled_x_offset;
x_start = x >> SCALE_SHIFT;
while (x_start < 0 && outbuf < outbuf_end)
{
process_pixel (run_weights + ((x >> (SCALE_SHIFT - SUBSAMPLE_BITS)) & SUBSAMPLE_MASK) * (filter->x.n * filter->y.n), filter->x.n, filter->y.n,
outbuf, dest_x, dest_channels, dest_has_alpha,
line_bufs, src_channels, src_has_alpha,
x >> SCALE_SHIFT, src_width,
check_size, tcolor1, tcolor2, pixel_func);
x += x_step;
x_start = x >> SCALE_SHIFT;
dest_x++;
outbuf += dest_channels;
}
new_outbuf = (*line_func) (run_weights, filter->x.n, filter->y.n,
outbuf, dest_x, dest_buf + (gsize)dest_rowstride *
i + run_end_index * dest_channels,
dest_channels, dest_has_alpha,
line_bufs, src_channels, src_has_alpha,
x, x_step, src_width, check_size, tcolor1,
tcolor2);
dest_x += (new_outbuf - outbuf) / dest_channels;
x = (dest_x - check_x + render_x0) * x_step + scaled_x_offset;
outbuf = new_outbuf;
while (outbuf < outbuf_end)
{
process_pixel (run_weights + ((x >> (SCALE_SHIFT - SUBSAMPLE_BITS)) & SUBSAMPLE_MASK) * (filter->x.n * filter->y.n), filter->x.n, filter->y.n,
outbuf, dest_x, dest_channels, dest_has_alpha,
line_bufs, src_channels, src_has_alpha,
x >> SCALE_SHIFT, src_width,
check_size, tcolor1, tcolor2, pixel_func);
x += x_step;
dest_x++;
outbuf += dest_channels;
}
y += y_step;
}
g_free (line_bufs);
g_free (filter_weights);
}
/* Compute weights for reconstruction by replication followed by
* sampling with a box filter
*/
static gboolean
tile_make_weights (PixopsFilterDimension *dim,
double scale)
{
int n = ceil (1 / scale + 1);
double *pixel_weights;
int offset;
int i;
pixel_weights = g_try_malloc_n (sizeof (double) * SUBSAMPLE, n);
if (pixel_weights == NULL)
return FALSE;
dim->n = n;
dim->offset = 0;
dim->weights = pixel_weights;
for (offset = 0; offset < SUBSAMPLE; offset++)
{
double x = (double)offset / SUBSAMPLE;
double a = x + 1 / scale;
for (i = 0; i < n; i++)
{
if (i < x)
{
if (i + 1 > x)
*(pixel_weights++) = (MIN (i + 1, a) - x) * scale;
else
*(pixel_weights++) = 0;
}
else
{
if (a > i)
*(pixel_weights++) = (MIN (i + 1, a) - i) * scale;
else
*(pixel_weights++) = 0;
}
}
}
return TRUE;
}
/* Compute weights for a filter that, for minification
* is the same as 'tiles', and for magnification, is bilinear
* reconstruction followed by a sampling with a delta function.
*/
static gboolean
bilinear_magnify_make_weights (PixopsFilterDimension *dim,
double scale)
{
double *pixel_weights;
int n;
int offset;
int i;
if (scale > 1.0) /* Linear */
{
n = 2;
dim->offset = 0.5 * (1 / scale - 1);
}
else /* Tile */
{
n = ceil (1.0 + 1.0 / scale);
dim->offset = 0.0;
}
dim->n = n;
dim->weights = g_try_malloc_n (sizeof (double) * SUBSAMPLE, n);
if (dim->weights == NULL)
return FALSE;
pixel_weights = dim->weights;
for (offset=0; offset < SUBSAMPLE; offset++)
{
double x = (double)offset / SUBSAMPLE;
if (scale > 1.0) /* Linear */
{
for (i = 0; i < n; i++)
*(pixel_weights++) = (((i == 0) ? (1 - x) : x) / scale) * scale;
}
else /* Tile */
{
double a = x + 1 / scale;
/* x
* ---------|--.-|----|--.-|------- SRC
* ------------|---------|--------- DEST
*/
for (i = 0; i < n; i++)
{
if (i < x)
{
if (i + 1 > x)
*(pixel_weights++) = (MIN (i + 1, a) - x) * scale;
else
*(pixel_weights++) = 0;
}
else
{
if (a > i)
*(pixel_weights++) = (MIN (i + 1, a) - i) * scale;
else
*(pixel_weights++) = 0;
}
}
}
}
return TRUE;
}
/* Computes the integral from b0 to b1 of
*
* f(x) = x; 0 <= x < 1
* f(x) = 0; otherwise
*
* We combine two of these to compute the convolution of
* a box filter with a triangular spike.
*/
static double
linear_box_half (double b0, double b1)
{
double a0, a1;
double x0, x1;
a0 = 0.;
a1 = 1.;
if (a0 < b0)
{
if (a1 > b0)
{
x0 = b0;
x1 = MIN (a1, b1);
}
else
return 0;
}
else
{
if (b1 > a0)
{
x0 = a0;
x1 = MIN (a1, b1);
}
else
return 0;
}
return 0.5 * (x1*x1 - x0*x0);
}
/* Compute weights for reconstructing with bilinear
* interpolation, then sampling with a box filter
*/
static gboolean
bilinear_box_make_weights (PixopsFilterDimension *dim,
double scale)
{
int n = ceil (1/scale + 3.0);
double *pixel_weights;
double w;
int offset, i;
pixel_weights = g_malloc_n (sizeof (double) * SUBSAMPLE, n);
if (pixel_weights == NULL)
return FALSE;
dim->offset = -1.0;
dim->n = n;
dim->weights = pixel_weights;
for (offset = 0; offset < SUBSAMPLE; offset++)
{
double x = (double)offset / SUBSAMPLE;
double a = x + 1 / scale;
for (i = 0; i < n; i++)
{
w = linear_box_half (0.5 + i - a, 0.5 + i - x);
w += linear_box_half (1.5 + x - i, 1.5 + a - i);
*(pixel_weights++) = w * scale;
}
}
return TRUE;
}
static gboolean
make_weights (PixopsFilter *filter,
PixopsInterpType interp_type,
double scale_x,
double scale_y)
{
switch (interp_type)
{
case PIXOPS_INTERP_NEAREST:
default:
g_assert_not_reached ();
return FALSE;
case PIXOPS_INTERP_TILES:
if (!tile_make_weights (&filter->x, scale_x))
return FALSE;
if (!tile_make_weights (&filter->y, scale_y))
{
g_free (filter->x.weights);
return FALSE;
}
return TRUE;
case PIXOPS_INTERP_BILINEAR:
if (!bilinear_magnify_make_weights (&filter->x, scale_x))
return FALSE;
if (!bilinear_magnify_make_weights (&filter->y, scale_y))
{
g_free (filter->x.weights);
return FALSE;
}
return TRUE;
case PIXOPS_INTERP_HYPER:
if (!bilinear_box_make_weights (&filter->x, scale_x))
return FALSE;
if (!bilinear_box_make_weights (&filter->y, scale_y))
{
g_free (filter->x.weights);
return FALSE;
}
return TRUE;
}
}
/* Two-step scaler begins */
/* make_filter_table() bloats out in VM usage and consumes 100% CPU for
* tens of seconds when downscaling by a large factor.
* https://bugzilla.gnome.org/show_bug.cgi?id=80925
* We work round this by doing extreme reductions in two steps.
*
* The excessive CPU usage is accompanied by an excessive RAM usage because
* make_weights() allocates two arrays of weights proportional in size to
* n_x = (1 / scale_x + 3) and n_y = (1 / scale_y + 3), then make_filter_table()
* allocates and fills an array of SUBSAMPLE * SUBSAMPLE * n_x * n_y doubles.
* Empirically, on machines with plenty of RAM, the execution time slopes upward
* when n_filters > 1000.
* SUBSAMPLE is 16 so each filter takes 16 x 16 doubles (8 bytes) = 2kb RAM.
* Limiting it to 1000 filters limits the scaler's RAM consumption to about 2MB
* which should be OK on machines with relatively little memory.
*
* GDK_INTER_BILINEAR, GDK_INTERP_TILES and GDK_INTER_HYPER all have
* similar symptoms; only GDK_INTERP_NEAREST does not need this trick.
**/
#define MAX_FILTERS 1000
/* Check whether prescaling is necessary to avoid the bug */
static gboolean
need_to_prescale (double scale_x,
double scale_y,
PixopsInterpType interp_type)
{
int n_x, n_y; /* See make_weights() */
/* The testsuite sets this to compare the results with and without it. */
if (g_getenv ("GDK_PIXBUF_DISABLE_TWO_STEP_SCALER"))
return FALSE;
/* Calculate the number of weights created in make_weights() */
switch (interp_type) {
case PIXOPS_INTERP_HYPER:
n_x = ceil (1 / scale_x + 3);
n_y = ceil (1 / scale_y + 3);
break;
case PIXOPS_INTERP_TILES:
case PIXOPS_INTERP_BILINEAR:
n_x = ceil (1 / scale_x + 1);
n_y = ceil (1 / scale_y + 1);
break;
case PIXOPS_INTERP_NEAREST:
/* Doesn't need the optimization */
return FALSE;
default:
g_assert_not_reached ();
}
/* Limit the number of filters created by make_filter_table(). */
return (n_x * n_y > MAX_FILTERS);
}
/* Prescale the source image.
* If successful, it changes the source buffer's parameters to reflect the
* half-scaled image and the scaling factors to reflect the scaling left to do.
* It returns a pointer to the new image data or NULL, so that the caller knows
* whether they have to free the temporary buffer or not.
*/
static guchar *
prescale (const guchar **src_bufp,
int *src_widthp,
int *src_heightp,
int *src_rowstridep,
int src_channels,
gboolean src_has_alpha,
double *scale_xp,
double *scale_yp,
PixopsInterpType interp_type)
{
/* Give local names to parameters that may be modified */
const guchar *src_buf = *src_bufp;
int src_width = *src_widthp;
int src_height = *src_heightp;
int src_rowstride = *src_rowstridep;
double scale_x = *scale_xp;
double scale_y = *scale_yp;
/* How much we prescale each axis by */
double prescale_x, prescale_y;
/* The prescaled image */
int tmp_width, tmp_height;
int tmp_rowstride;
int tmp_channels;
gboolean tmp_has_alpha;
guchar *tmp_buf;
/* The time taken by make_filter_table() is roughly proportional to
* 1/scale_x * 1/scale_y, i.e. to the area reduction factor, so we
* reduce the image in two steps, each of which reduces the total area
* by the same factor. */
prescale_x = sqrt (scale_x);
prescale_y = sqrt (scale_y);
/* Scale the whole source image into a top-left-aligned temporary pixbuf.
* render_[xy][01] are done in the final scaling, not here, as they are
* measured in the coordinate system of the scaled image. */
tmp_width = lrint (src_width * prescale_x);
tmp_height = lrint (src_height * prescale_y);
/* We are below the gdk_ interface, so create the temp image manually.
* Code copied from gdk_pixbuf_new() */
tmp_channels = src_channels;
tmp_has_alpha = src_has_alpha;
tmp_rowstride = ((tmp_width * tmp_channels) + 3) & ~3;
tmp_buf = g_try_malloc_n (tmp_height, tmp_rowstride);
if (!tmp_buf)
return NULL; /* Skip the prescaling */
/* Prescale to an intermediate size */
_pixops_scale (tmp_buf, tmp_width, tmp_height, tmp_rowstride,
tmp_channels, tmp_has_alpha, src_buf, src_width,
src_height, src_rowstride, src_channels, src_has_alpha,
0, 0, tmp_width, tmp_height, 0.0, 0.0,
prescale_x, prescale_y,
interp_type);
/* The second call to the scaler reads from the prescaled image */
*src_bufp = tmp_buf;
*src_widthp = tmp_width;
*src_heightp = tmp_height;
*src_rowstridep = tmp_rowstride;
/* Calculate how much scaling is left to do */
*scale_xp /= prescale_x;
*scale_yp /= prescale_y;
return tmp_buf;
}
/* End of two-step scaler */
static void
_pixops_composite_color_real (guchar *dest_buf,
int render_x0,
int render_y0,
int render_x1,
int render_y1,
int dest_rowstride,
int dest_channels,
gboolean dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
gboolean src_has_alpha,
double scale_x,
double scale_y,
PixopsInterpType interp_type,
int overall_alpha,
int check_x,
int check_y,
int check_size,
guint32 color1,
guint32 color2)
{
PixopsFilter filter;
PixopsLineFunc line_func;
guchar *tmp_buf = NULL;
#ifdef USE_MMX
gboolean found_mmx = _pixops_have_mmx ();
#endif
g_return_if_fail (!(dest_channels == 3 && dest_has_alpha));
g_return_if_fail (!(src_channels == 3 && src_has_alpha));
if (scale_x == 0 || scale_y == 0)
return;
if (interp_type == PIXOPS_INTERP_NEAREST)
{
pixops_composite_color_nearest (dest_buf, render_x0, render_y0,
render_x1, render_y1, dest_rowstride,
dest_channels, dest_has_alpha, src_buf,
src_width, src_height, src_rowstride,
src_channels, src_has_alpha, scale_x,
scale_y, overall_alpha, check_x, check_y,
check_size, color1, color2);
return;
}
if (need_to_prescale (scale_x, scale_y, interp_type))
tmp_buf = prescale (&src_buf, &src_width, &src_height, &src_rowstride,
src_channels, src_has_alpha,
&scale_x, &scale_y, interp_type);
filter.overall_alpha = overall_alpha / 255.;
if (!make_weights (&filter, interp_type, scale_x, scale_y))
return;
#ifdef USE_MMX
if (filter.x.n == 2 && filter.y.n == 2 &&
dest_channels == 4 && src_channels == 4 &&
src_has_alpha && !dest_has_alpha && found_mmx)
line_func = composite_line_color_22_4a4_mmx_stub;
else
#endif
line_func = composite_line_color;
pixops_process (dest_buf, render_x0, render_y0, render_x1, render_y1,
dest_rowstride, dest_channels, dest_has_alpha,
src_buf, src_width, src_height, src_rowstride, src_channels,
src_has_alpha, scale_x, scale_y, check_x, check_y, check_size, color1, color2,
&filter, line_func, composite_pixel_color);
g_free (filter.x.weights);
g_free (filter.y.weights);
if (tmp_buf)
g_free (tmp_buf);
}
void
_pixops_composite_color (guchar *dest_buf,
int dest_width,
int dest_height,
int dest_rowstride,
int dest_channels,
gboolean dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
gboolean src_has_alpha,
int dest_x,
int dest_y,
int dest_region_width,
int dest_region_height,
double offset_x,
double offset_y,
double scale_x,
double scale_y,
PixopsInterpType interp_type,
int overall_alpha,
int check_x,
int check_y,
int check_size,
guint32 color1,
guint32 color2)
{
guchar *new_dest_buf;
int render_x0;
int render_y0;
int render_x1;
int render_y1;
if (!src_has_alpha && overall_alpha == 255)
{
_pixops_scale (dest_buf, dest_width, dest_height, dest_rowstride,
dest_channels, dest_has_alpha, src_buf, src_width,
src_height, src_rowstride, src_channels, src_has_alpha,
dest_x, dest_y, dest_region_width, dest_region_height,
offset_x, offset_y, scale_x, scale_y, interp_type);
return;
}
new_dest_buf = dest_buf + dest_y * dest_rowstride + dest_x *
dest_channels;
render_x0 = dest_x - offset_x;
render_y0 = dest_y - offset_y;
render_x1 = dest_x + dest_region_width - offset_x;
render_y1 = dest_y + dest_region_height - offset_y;
_pixops_composite_color_real (new_dest_buf, render_x0, render_y0, render_x1,
render_y1, dest_rowstride, dest_channels,
dest_has_alpha, src_buf, src_width,
src_height, src_rowstride, src_channels,
src_has_alpha, scale_x, scale_y,
(PixopsInterpType)interp_type, overall_alpha,
check_x, check_y, check_size, color1, color2);
}
/**
* _pixops_composite_real:
* @dest_buf: pointer to location to store result
* @render_x0: x0 of region of scaled source to store into @dest_buf
* @render_y0: y0 of region of scaled source to store into @dest_buf
* @render_x1: x1 of region of scaled source to store into @dest_buf
* @render_y1: y1 of region of scaled source to store into @dest_buf
* @dest_rowstride: rowstride of @dest_buf
* @dest_channels: number of channels in @dest_buf
* @dest_has_alpha: whether @dest_buf has alpha
* @src_buf: pointer to source pixels
* @src_width: width of source (used for clipping)
* @src_height: height of source (used for clipping)
* @src_rowstride: rowstride of source
* @src_channels: number of channels in @src_buf
* @src_has_alpha: whether @src_buf has alpha
* @scale_x: amount to scale source by in X direction
* @scale_y: amount to scale source by in Y direction
* @interp_type: type of enumeration
* @overall_alpha: overall alpha factor to multiply source by
*
* Scale source buffer by scale_x / scale_y, then composite a given rectangle
* of the result into the destination buffer.
**/
static void
_pixops_composite_real (guchar *dest_buf,
int render_x0,
int render_y0,
int render_x1,
int render_y1,
int dest_rowstride,
int dest_channels,
gboolean dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
gboolean src_has_alpha,
double scale_x,
double scale_y,
PixopsInterpType interp_type,
int overall_alpha)
{
PixopsFilter filter;
PixopsLineFunc line_func;
guchar *tmp_buf = NULL;
#ifdef USE_MMX
gboolean found_mmx = _pixops_have_mmx ();
#endif
g_return_if_fail (!(dest_channels == 3 && dest_has_alpha));
g_return_if_fail (!(src_channels == 3 && src_has_alpha));
if (scale_x == 0 || scale_y == 0)
return;
if (interp_type == PIXOPS_INTERP_NEAREST)
{
if (scale_x == 1.0 && scale_y == 1.0)
pixops_composite_nearest_noscale (dest_buf, render_x0, render_y0, render_x1, render_y1,
dest_rowstride, dest_channels, dest_has_alpha,
src_buf, src_width, src_height, src_rowstride, src_channels,
src_has_alpha, overall_alpha);
else
pixops_composite_nearest (dest_buf, render_x0, render_y0, render_x1, render_y1,
dest_rowstride, dest_channels, dest_has_alpha,
src_buf, src_width, src_height, src_rowstride, src_channels,
src_has_alpha, scale_x, scale_y, overall_alpha);
return;
}
if (need_to_prescale (scale_x, scale_y, interp_type))
tmp_buf = prescale (&src_buf, &src_width, &src_height, &src_rowstride,
src_channels, src_has_alpha,
&scale_x, &scale_y, interp_type);
filter.overall_alpha = overall_alpha / 255.;
if (!make_weights (&filter, interp_type, scale_x, scale_y))
return;
if (filter.x.n == 2 && filter.y.n == 2 && dest_channels == 4 &&
src_channels == 4 && src_has_alpha && !dest_has_alpha)
{
#ifdef USE_MMX
if (found_mmx)
line_func = composite_line_22_4a4_mmx_stub;
else
#endif
line_func = composite_line_22_4a4;
}
else
line_func = composite_line;
pixops_process (dest_buf, render_x0, render_y0, render_x1, render_y1,
dest_rowstride, dest_channels, dest_has_alpha,
src_buf, src_width, src_height, src_rowstride, src_channels,
src_has_alpha, scale_x, scale_y, 0, 0, 0, 0, 0,
&filter, line_func, composite_pixel);
g_free (filter.x.weights);
g_free (filter.y.weights);
if (tmp_buf)
g_free (tmp_buf);
}
void
_pixops_composite (guchar *dest_buf,
int dest_width,
int dest_height,
int dest_rowstride,
int dest_channels,
int dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
int src_has_alpha,
int dest_x,
int dest_y,
int dest_region_width,
int dest_region_height,
double offset_x,
double offset_y,
double scale_x,
double scale_y,
PixopsInterpType interp_type,
int overall_alpha)
{
guchar *new_dest_buf;
int render_x0;
int render_y0;
int render_x1;
int render_y1;
if (!src_has_alpha && overall_alpha == 255)
{
_pixops_scale (dest_buf, dest_width, dest_height, dest_rowstride,
dest_channels, dest_has_alpha, src_buf, src_width,
src_height, src_rowstride, src_channels, src_has_alpha,
dest_x, dest_y, dest_region_width, dest_region_height,
offset_x, offset_y, scale_x, scale_y, interp_type);
return;
}
#ifdef USE_MEDIALIB
pixops_medialib_composite (dest_buf, dest_width, dest_height, dest_rowstride,
dest_channels, dest_has_alpha, src_buf,
src_width, src_height, src_rowstride,
src_channels, src_has_alpha, dest_x, dest_y,
dest_region_width, dest_region_height, offset_x,
offset_y, scale_x, scale_y,
(PixopsInterpType)interp_type, overall_alpha);
return;
#endif
new_dest_buf = dest_buf + (gsize)dest_y * dest_rowstride + (gsize)dest_x * dest_channels;
render_x0 = dest_x - offset_x;
render_y0 = dest_y - offset_y;
render_x1 = dest_x + dest_region_width - offset_x;
render_y1 = dest_y + dest_region_height - offset_y;
_pixops_composite_real (new_dest_buf, render_x0, render_y0, render_x1,
render_y1, dest_rowstride, dest_channels,
dest_has_alpha, src_buf, src_width, src_height,
src_rowstride, src_channels, src_has_alpha, scale_x,
scale_y, (PixopsInterpType)interp_type,
overall_alpha);
}
#ifdef USE_MEDIALIB
static void
medialib_get_interpolation (mlInterp * ml_interp,
PixopsInterpType interp_type,
double scale_x,
double scale_y,
double overall_alpha)
{
mlib_s32 leftPadding, topPadding;
ml_interp->interp_table = NULL;
/*
* medialib 2.1 and later supports scaling with user-defined interpolation
* tables, so this logic is used.
*
* bilinear_magnify_make_weights builds an interpolation table of size 2x2 if
* the scale factor >= 1.0 and "ceil (1.0 + 1.0/scale)" otherwise. These map
* most closely to MLIB_BILINEAR, which uses an interpolation table of size
* 2x2.
*
* tile_make_weights builds an interpolation table of size 2x2 if the scale
* factor >= 1.0 and "ceil (1.0 + 1.0/scale)" otherwise. These map most
* closely to MLIB_BILINEAR, which uses an interpolation table of size 2x2.
*
* bilinear_box_make_weights builds an interpolation table of size 4x4 if the
* scale factor >= 1.0 and "ceil (1.0 + 1.0/scale)" otherwise. These map most
* closely to MLIB_BICUBIC, which uses an interpolation table of size 4x4.
*
* PIXOPS_INTERP_NEAREST calls pixops_scale_nearest which does not use an
* interpolation table. This maps to MLIB_NEAREST.
*/
switch (interp_type)
{
case PIXOPS_INTERP_BILINEAR:
bilinear_magnify_make_weights (&(ml_interp->po_filter.x), scale_x);
bilinear_magnify_make_weights (&(ml_interp->po_filter.y), scale_y);
leftPadding = 0;
topPadding = 0;
if (scale_x <= 1.0)
ml_interp->tx = 0.5 * (1 - scale_x);
else
ml_interp->tx = 0.0;
if (scale_y <= 1.0)
ml_interp->ty = 0.5 * (1 - scale_y);
else
ml_interp->ty = 0.0;
break;
case PIXOPS_INTERP_TILES:
tile_make_weights (&(ml_interp->po_filter.x), scale_x);
tile_make_weights (&(ml_interp->po_filter.y), scale_y);
leftPadding = 0;
topPadding = 0;
ml_interp->tx = 0.5 * (1 - scale_x);
ml_interp->ty = 0.5 * (1 - scale_y);
break;
case PIXOPS_INTERP_HYPER:
bilinear_box_make_weights (&(ml_interp->po_filter.x), scale_x);
bilinear_box_make_weights (&(ml_interp->po_filter.y), scale_y);
leftPadding = 1;
topPadding = 1;
ml_interp->tx = 0.5 * (1 - scale_x);
ml_interp->ty = 0.5 * (1 - scale_y);
break;
case PIXOPS_INTERP_NEAREST:
default:
/*
* Note that this function should not be called in the
* PIXOPS_INTERP_NEAREST case since it does not use an interpolation
* table.
*/
g_assert_not_reached ();
break;
}
/*
* If overall_alpha is not 1.0, then multiply the vectors built by the
* sqrt (overall_alpha). This will cause overall_alpha to get evenly
* blended across both axis.
*
* Note there is no need to multiply the vectors built by the various
* make-weight functions by sqrt (overall_alpha) since the make-weight
* functions are called with overall_alpha hardcoded to 1.0.
*/
if (overall_alpha != 1.0)
{
double sqrt_alpha = sqrt (overall_alpha);
int i;
for (i=0; i < SUBSAMPLE * ml_interp->po_filter.x.n; i++)
ml_interp->po_filter.x.weights[i] *= sqrt_alpha;
for (i=0; i < SUBSAMPLE * ml_interp->po_filter.y.n; i++)
ml_interp->po_filter.y.weights[i] *= sqrt_alpha;
}
ml_interp->interp_table = (void *) mlib_ImageInterpTableCreate (MLIB_DOUBLE,
ml_interp->po_filter.x.n, ml_interp->po_filter.y.n, leftPadding,
topPadding, SUBSAMPLE_BITS, SUBSAMPLE_BITS, 8,
ml_interp->po_filter.x.weights, ml_interp->po_filter.y.weights);
g_free (ml_interp->po_filter.x.weights);
g_free (ml_interp->po_filter.y.weights);
}
static void
pixops_medialib_composite (guchar *dest_buf,
int dest_width,
int dest_height,
int dest_rowstride,
int dest_channels,
int dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
int src_has_alpha,
int dest_x,
int dest_y,
int dest_region_width,
int dest_region_height,
double offset_x,
double offset_y,
double scale_x,
double scale_y,
PixopsInterpType interp_type,
int overall_alpha)
{
mlib_blend blend;
g_return_if_fail (!(dest_channels == 3 && dest_has_alpha));
g_return_if_fail (!(src_channels == 3 && src_has_alpha));
if (scale_x == 0 || scale_y == 0)
return;
if (!medialib_initialized)
_pixops_use_medialib ();
if (!use_medialib)
{
/* Use non-mediaLib version */
_pixops_composite_real (dest_buf + (gsize)dest_y * dest_rowstride + (gsize)dest_x *
dest_channels, dest_x - offset_x, dest_y -
offset_y, dest_x + dest_region_width - offset_x,
dest_y + dest_region_height - offset_y,
dest_rowstride, dest_channels, dest_has_alpha,
src_buf, src_width, src_height, src_rowstride,
src_channels, src_has_alpha, scale_x, scale_y,
interp_type, overall_alpha);
}
else
{
mlInterp ml_interp;
mlib_image img_src, img_dest;
double ml_offset_x, ml_offset_y;
if (!src_has_alpha && overall_alpha == 255 &&
dest_channels <= src_channels)
{
pixops_medialib_scale (dest_buf, dest_region_width,
dest_region_height, dest_rowstride,
dest_channels, dest_has_alpha, src_buf,
src_width, src_height, src_rowstride,
src_channels, src_has_alpha, dest_x, dest_y,
dest_region_width, dest_region_height,
offset_x, offset_y, scale_x, scale_y,
interp_type);
return;
}
mlib_ImageSetStruct (&img_src, MLIB_BYTE, src_channels,
src_width, src_height, src_rowstride, src_buf);
if (dest_x == 0 && dest_y == 0 &&
dest_width == dest_region_width &&
dest_height == dest_region_height)
{
mlib_ImageSetStruct (&img_dest, MLIB_BYTE, dest_channels,
dest_width, dest_height, dest_rowstride,
dest_buf);
}
else
{
mlib_u8 *data = dest_buf + (gsize)dest_y * dest_rowstride +
(gsize)dest_x * dest_channels;
mlib_ImageSetStruct (&img_dest, MLIB_BYTE, dest_channels,
dest_region_width, dest_region_height,
dest_rowstride, data);
}
ml_offset_x = floor (offset_x) - dest_x;
ml_offset_y = floor (offset_y) - dest_y;
if (interp_type == PIXOPS_INTERP_NEAREST)
{
blend = src_has_alpha ? MLIB_BLEND_GTK_SRC_OVER2 : MLIB_BLEND_GTK_SRC;
mlib_ImageZoomTranslateBlend (&img_dest,
&img_src,
scale_x,
scale_y,
ml_offset_x,
ml_offset_y,
MLIB_NEAREST,
MLIB_EDGE_SRC_EXTEND_INDEF,
blend,
overall_alpha,
1);
}
else
{
blend = src_has_alpha ? MLIB_BLEND_GTK_SRC_OVER : MLIB_BLEND_GTK_SRC;
if (interp_type == PIXOPS_INTERP_BILINEAR &&
scale_x > 1.0 && scale_y > 1.0)
{
mlib_ImageZoomTranslateBlend (&img_dest,
&img_src,
scale_x,
scale_y,
ml_offset_x,
ml_offset_y,
MLIB_BILINEAR,
MLIB_EDGE_SRC_EXTEND_INDEF,
blend,
overall_alpha,
1);
}
else
{
medialib_get_interpolation (&ml_interp, interp_type, scale_x,
scale_y, overall_alpha/255.0);
if (ml_interp.interp_table != NULL)
{
mlib_ImageZoomTranslateTableBlend (&img_dest,
&img_src,
scale_x,
scale_y,
ml_offset_x + ml_interp.tx,
ml_offset_y + ml_interp.ty,
ml_interp.interp_table,
MLIB_EDGE_SRC_EXTEND_INDEF,
blend,
1);
mlib_ImageInterpTableDelete (ml_interp.interp_table);
}
else
{
/* Should not happen - Use non-mediaLib version */
_pixops_composite_real (dest_buf + (gsize)dest_y * dest_rowstride +
(gsize)dest_x * dest_channels,
dest_x - offset_x, dest_y - offset_y,
dest_x + dest_region_width - offset_x,
dest_y + dest_region_height - offset_y,
dest_rowstride, dest_channels,
dest_has_alpha, src_buf, src_width,
src_height, src_rowstride,
src_channels, src_has_alpha, scale_x,
scale_y, interp_type, overall_alpha);
}
}
}
}
}
#endif
static void
_pixops_scale_real (guchar *dest_buf,
int render_x0,
int render_y0,
int render_x1,
int render_y1,
int dest_rowstride,
int dest_channels,
gboolean dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
gboolean src_has_alpha,
double scale_x,
double scale_y,
PixopsInterpType interp_type)
{
PixopsFilter filter;
PixopsLineFunc line_func;
guchar *tmp_buf = NULL; /* Temporary image for two-step scaling */
#ifdef USE_MMX
gboolean found_mmx = _pixops_have_mmx ();
#endif
g_return_if_fail (!(dest_channels == 3 && dest_has_alpha));
g_return_if_fail (!(src_channels == 3 && src_has_alpha));
g_return_if_fail (!(src_has_alpha && !dest_has_alpha));
if (scale_x == 0 || scale_y == 0)
return;
if (interp_type == PIXOPS_INTERP_NEAREST)
{
pixops_scale_nearest (dest_buf, render_x0, render_y0, render_x1,
render_y1, dest_rowstride, dest_channels,
dest_has_alpha, src_buf, src_width, src_height,
src_rowstride, src_channels, src_has_alpha,
scale_x, scale_y);
return;
}
if (need_to_prescale (scale_x, scale_y, interp_type))
tmp_buf = prescale (&src_buf, &src_width, &src_height, &src_rowstride,
src_channels, src_has_alpha,
&scale_x, &scale_y, interp_type);
filter.overall_alpha = 1.0;
if (!make_weights (&filter, interp_type, scale_x, scale_y))
return;
if (filter.x.n == 2 && filter.y.n == 2 && dest_channels == 3 && src_channels == 3)
{
#ifdef USE_MMX
if (found_mmx)
line_func = scale_line_22_33_mmx_stub;
else
#endif
line_func = scale_line_22_33;
}
else
line_func = scale_line;
pixops_process (dest_buf, render_x0, render_y0, render_x1, render_y1,
dest_rowstride, dest_channels, dest_has_alpha,
src_buf, src_width, src_height, src_rowstride, src_channels,
src_has_alpha, scale_x, scale_y, 0, 0, 0, 0, 0,
&filter, line_func, scale_pixel);
g_free (filter.x.weights);
g_free (filter.y.weights);
g_clear_pointer (&tmp_buf, g_free);
}
void
_pixops_scale (guchar *dest_buf,
int dest_width,
int dest_height,
int dest_rowstride,
int dest_channels,
int dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
int src_has_alpha,
int dest_x,
int dest_y,
int dest_region_width,
int dest_region_height,
double offset_x,
double offset_y,
double scale_x,
double scale_y,
PixopsInterpType interp_type)
{
guchar *new_dest_buf;
int render_x0;
int render_y0;
int render_x1;
int render_y1;
#ifdef USE_MEDIALIB
pixops_medialib_scale (dest_buf, dest_width, dest_height, dest_rowstride,
dest_channels, dest_has_alpha, src_buf, src_width,
src_height, src_rowstride, src_channels,
src_has_alpha, dest_x, dest_y, dest_region_width,
dest_region_height, offset_x, offset_y, scale_x,
scale_y, (PixopsInterpType)interp_type);
return;
#endif
new_dest_buf = dest_buf + (gsize)dest_y * dest_rowstride + (gsize)dest_x * dest_channels;
render_x0 = dest_x - offset_x;
render_y0 = dest_y - offset_y;
render_x1 = dest_x + dest_region_width - offset_x;
render_y1 = dest_y + dest_region_height - offset_y;
_pixops_scale_real (new_dest_buf, render_x0, render_y0, render_x1,
render_y1, dest_rowstride, dest_channels,
dest_has_alpha, src_buf, src_width, src_height,
src_rowstride, src_channels, src_has_alpha,
scale_x, scale_y, (PixopsInterpType)interp_type);
}
#ifdef USE_MEDIALIB
static void
pixops_medialib_scale (guchar *dest_buf,
int dest_width,
int dest_height,
int dest_rowstride,
int dest_channels,
int dest_has_alpha,
const guchar *src_buf,
int src_width,
int src_height,
int src_rowstride,
int src_channels,
int src_has_alpha,
int dest_x,
int dest_y,
int dest_region_width,
int dest_region_height,
double offset_x,
double offset_y,
double scale_x,
double scale_y,
PixopsInterpType interp_type)
{
if (scale_x == 0 || scale_y == 0)
return;
if (!medialib_initialized)
_pixops_use_medialib ();
/*
* We no longer support mediaLib 2.1 because it has a core dumping problem
* in the mlib_ImageZoomTranslateTable function that has been corrected in
* 2.2. Although the mediaLib_zoom function could be used, it does not
* work properly if the source and destination images have different
* values for "has_alpha" or "num_channels". The complicated if-logic
* required to support both versions is not worth supporting
* mediaLib 2.1 moving forward.
*/
if (!use_medialib)
{
_pixops_scale_real (dest_buf + (gsize)dest_y * dest_rowstride + (gsize)dest_x *
dest_channels, dest_x - offset_x, dest_y - offset_y,
dest_x + dest_region_width - offset_x,
dest_y + dest_region_height - offset_y,
dest_rowstride, dest_channels, dest_has_alpha,
src_buf, src_width, src_height, src_rowstride,
src_channels, src_has_alpha, scale_x, scale_y,
interp_type);
}
else
{
mlInterp ml_interp;
mlib_image img_orig_src, img_src, img_dest;
double ml_offset_x, ml_offset_y;
guchar *tmp_buf = NULL;
mlib_ImageSetStruct (&img_orig_src, MLIB_BYTE, src_channels, src_width,
src_height, src_rowstride, src_buf);
if (dest_x == 0 && dest_y == 0 &&
dest_width == dest_region_width &&
dest_height == dest_region_height)
{
mlib_ImageSetStruct (&img_dest, MLIB_BYTE, dest_channels,
dest_width, dest_height, dest_rowstride,
dest_buf);
}
else
{
mlib_u8 *data = dest_buf + (gsize)dest_y * dest_rowstride +
(gsize)dest_x * dest_channels;
mlib_ImageSetStruct (&img_dest, MLIB_BYTE, dest_channels,
dest_region_width, dest_region_height,
dest_rowstride, data);
}
ml_offset_x = floor (offset_x) - dest_x;
ml_offset_y = floor (offset_y) - dest_y;
/*
* Note that zoomTranslate and zoomTranslateTable are faster
* than zoomTranslateBlend and zoomTranslateTableBlend. However
* the faster functions only work in the following case:
*
* if (src_channels == dest_channels &&
* (!src_alpha && interp_table != PIXOPS_INTERP_NEAREST))
*
* We use the faster versions if we can.
*
* Note when the interp_type is BILINEAR and the interpolation
* table will be size 2x2 (when both x/y scale factors > 1.0),
* then we do not bother building the interpolation table. In
* this case we can just use MLIB_BILINEAR, which is faster than
* using a specified interpolation table.
*/
img_src = img_orig_src;
if (!src_has_alpha)
{
if (src_channels > dest_channels)
{
int channels = 3;
int rowstride = (channels * src_width + 3) & ~3;
tmp_buf = g_malloc_n (src_rowstride, src_height);
if (src_buf != NULL)
{
src_channels = channels;
src_rowstride = rowstride;
mlib_ImageSetStruct (&img_src, MLIB_BYTE, src_channels,
src_width, src_height, src_rowstride,
tmp_buf);
mlib_ImageChannelExtract (&img_src, &img_orig_src, 0xE);
}
}
}
if (interp_type == PIXOPS_INTERP_NEAREST)
{
if (src_channels == dest_channels)
{
mlib_ImageZoomTranslate (&img_dest,
&img_src,
scale_x,
scale_y,
ml_offset_x,
ml_offset_y,
MLIB_NEAREST,
MLIB_EDGE_SRC_EXTEND_INDEF);
}
else
{
mlib_ImageZoomTranslateBlend (&img_dest,
&img_src,
scale_x,
scale_y,
ml_offset_x,
ml_offset_y,
MLIB_NEAREST,
MLIB_EDGE_SRC_EXTEND_INDEF,
MLIB_BLEND_GTK_SRC,
1.0,
1);
}
}
else if (src_channels == dest_channels && !src_has_alpha)
{
if (interp_type == PIXOPS_INTERP_BILINEAR &&
scale_x > 1.0 && scale_y > 1.0)
{
mlib_ImageZoomTranslate (&img_dest,
&img_src,
scale_x,
scale_y,
ml_offset_x,
ml_offset_y,
MLIB_BILINEAR,
MLIB_EDGE_SRC_EXTEND_INDEF);
}
else
{
medialib_get_interpolation (&ml_interp, interp_type,
scale_x, scale_y, 1.0);
if (ml_interp.interp_table != NULL)
{
mlib_ImageZoomTranslateTable (&img_dest,
&img_src,
scale_x,
scale_y,
ml_offset_x + ml_interp.tx,
ml_offset_y + ml_interp.ty,
ml_interp.interp_table,
MLIB_EDGE_SRC_EXTEND_INDEF);
mlib_ImageInterpTableDelete (ml_interp.interp_table);
}
else
{
/* Should not happen. */
mlib_filter ml_filter;
switch (interp_type)
{
case PIXOPS_INTERP_BILINEAR:
ml_filter = MLIB_BILINEAR;
break;
case PIXOPS_INTERP_TILES:
ml_filter = MLIB_BILINEAR;
break;
case PIXOPS_INTERP_HYPER:
ml_filter = MLIB_BICUBIC;
break;
}
mlib_ImageZoomTranslate (&img_dest,
&img_src,
scale_x,
scale_y,
ml_offset_x,
ml_offset_y,
ml_filter,
MLIB_EDGE_SRC_EXTEND_INDEF);
}
}
}
/* Deal with case where src_channels != dest_channels || src_has_alpha */
else if (interp_type == PIXOPS_INTERP_BILINEAR &&
scale_x > 1.0 && scale_y > 1.0)
{
mlib_ImageZoomTranslateBlend (&img_dest,
&img_src,
scale_x,
scale_y,
ml_offset_x,
ml_offset_y,
MLIB_BILINEAR,
MLIB_EDGE_SRC_EXTEND_INDEF,
MLIB_BLEND_GTK_SRC,
1.0,
1);
}
else
{
medialib_get_interpolation (&ml_interp, interp_type,
scale_x, scale_y, 1.0);
if (ml_interp.interp_table != NULL)
{
mlib_ImageZoomTranslateTableBlend (&img_dest,
&img_src,
scale_x,
scale_y,
ml_offset_x + ml_interp.tx,
ml_offset_y + ml_interp.ty,
ml_interp.interp_table,
MLIB_EDGE_SRC_EXTEND_INDEF,
MLIB_BLEND_GTK_SRC,
1);
mlib_ImageInterpTableDelete (ml_interp.interp_table);
}
else
{
mlib_filter ml_filter;
switch (interp_type)
{
case PIXOPS_INTERP_BILINEAR:
ml_filter = MLIB_BILINEAR;
break;
case PIXOPS_INTERP_TILES:
ml_filter = MLIB_BILINEAR;
break;
case PIXOPS_INTERP_HYPER:
ml_filter = MLIB_BICUBIC;
break;
}
mlib_ImageZoomTranslate (&img_dest,
&img_src,
scale_x,
scale_y,
ml_offset_x,
ml_offset_y,
ml_filter,
MLIB_EDGE_SRC_EXTEND_INDEF);
}
}
if (tmp_buf != NULL)
g_free (tmp_buf);
}
}
#endif